Title :
Defect engineering in MBE grown GaAs based materials
Author :
Specht, P. ; Cich, M.J. ; Zhao, R. ; Jager, N.D. ; Gebauer, J. ; Borner, F. ; Krause-Rehberg, R. ; Luysberg, M. ; Weber, E.R.
Author_Institution :
Dept. of Mater. Sci. & Eng., California Univ., Berkeley, CA, USA
Abstract :
Complete control of the native point defect concentration in GaAs grown by MBE at low temperatures (LT-GaAs) can be achieved by the introduction of Be acceptors. Near intrinsic electrical resistivity, ultrahigh breakdown fields, and simultaneously ultrashort carrier lifetimes were obtained. Generally, Be-doping is found to be beneficial for the thermal stability of the epilayers. Maximal stability is reached using Be doping levels similar to the As antisite defect concentration (balanced doping). Additionally, the increased thermal stability of Be-doped LT-GaAs can be utilized to introduce and stabilize ultrahigh Be-doping concentrations which results in p-conductive epilayers with record hole concentrations approaching 4×1020/cm3 . The present work is focused on exploring possible reasons for the thermal stabilization and the increase in maximum Be incorporation
Keywords :
III-V semiconductors; antisite defects; beryllium; carrier lifetime; electric breakdown; electrical resistivity; gallium arsenide; heavily doped semiconductors; hole density; impurity states; molecular beam epitaxial growth; point defects; semiconductor doping; semiconductor epitaxial layers; semiconductor growth; thermal stability; As antisite defect concentration; Be acceptors; Be-doping; GaAs:Be; LT-GaAs; MBE grown GaAs based materials; balanced doping; defect engineering; epilayers; hole concentration; low temperatures; native point defect concentration; near intrinsic electrical resistivity; p-conductive epilayers; thermal stability; thermal stabilization; ultrahigh Be-doping concentrations; ultrahigh breakdown fields; ultrashort carrier lifetimes; Capacitive sensors; Doping; Electric breakdown; Electric resistance; Gallium arsenide; Materials science and technology; Molecular beam epitaxial growth; Temperature control; Temperature measurement; Thermal stability;
Conference_Titel :
Semiconducting and Insulating Materials Conference, 2000. SIMC-XI. International
Conference_Location :
Canberra, ACT
Print_ISBN :
0-7803-5814-7
DOI :
10.1109/SIM.2000.939200
